Real time total asset visibility system

ABSTRACT

A system and method for tracking articles and monitoring them on a real time basis comprising the use of a tag and one or more reader disposed within a locale being monitored and structured to communicate received data transmission to or from a host controller, for additional administrative processing in terms of determining the existence, location, state and/or movement of various articles with which the plurality of tags are directly associated. Depending on their category the tags may be activated by either entering an electric field of a predetermined first frequency or by receiving an activation signal from the reader assembly also transmitted at the first predetermined frequency. Communication between the tags and the reader occurs at a second frequency being different from the first frequency.

CLAIM OF PRIORITY

The present application is a continuation-in-part application of patent application Ser. No. 10/946,582, filed Sep. 21, 2004, which has matured into U.S. Pat. No. 7,082,344 on Jul. 25, 2006, which is also a continuation-in-part of patent application Ser. No. 10/253,254, filed Sep. 24, 2002, which has matured into U.S. Pat. No. 6,804,578 on Oct. 12, 2004, which is a continuation-in-part of patent application Ser. No. 09/976,734, filed Oct. 12, 2001, now U.S. Pat. No. 6,662,068, issued Dec. 9, 2003 incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention is directed to a system which allows effective inventory control and extensive tracking capabilities of a plurality of articles by providing total real time access to a monitored locale in order to establish the existence, location and/or direction of movement of the articles. A plurality of tags are associated with the various articles being monitored, at least some of which include multi-frequency and uni-directional or multi-directional communication capabilities which at least partially serve to extend the operative range between the tags and a reader assembly in order to efficiently perform the monitoring procedure. Furthermore, one or more auxiliary sensor devices or probes may be associated and/or integrated with the tag or reader so as to provide secondary information relating to a variety of conditions such as position, temperature, pressure, vibration, etc.

2. Description of the Related Art

The monitoring of a variety of different articles, products, etc. through the use of “tags” secured to or otherwise associated with the various articles has been in use for many years. Moreover, various attempts to modify this type of tracking and inventory control have been made so as to adapt a tagging system for use in a variety of different applications. Such known applications include, but are not limited to, warehouses, retail outlets, industrial manufacturing sites, and almost any location where the variety or articles or products being monitored are manufactured, transported, stored, sold, etc.

In its more simplistic form, the tagging of articles has been associated with the display of pricing information in association with the shelving of various products, such as in retail outlets. Pricing and inventory controls are sometimes maintained through the inclusion of coded data on the tags, such as by means of bar codes, which are determinative of the identity, price, etc, of the various products. Initially, and as is currently being used, these types of “shelf tags” have been simply constructed and include various information displayed thereon. Such displayed information, when coded as set forth above, can be read by various types of optical or digital scanners.

While shelf tags of the type set forth above are generally considered to be operative for less sophisticated applications, they are commonly recognized as being inefficient and cumbersome for use in many areas of commerce associated with the storage, transport, manufacture, etc, of various types of products or articles being monitored. As one example, the updating the information frequently requires complete replacement of the tags thereby at least partially defeating the goal of efficient inventory, tracking and pricing controls for which such systems were primarily intended.

To overcome the above noted problems associated with shelf tags, attempts have been made to develop more sophisticated electronic tags which are associated with some type of display facilities. Typically known electronic tags and their attendant systems, of the type referred to wherein require the use of complicated circuitry and cooperative electronic control components in order to affect their installation and use. Another major draw back associated with devices of this type is that in order to maintain an efficient and accurate display a continuous supply of power must be maintained. The maintenance of such power is limited resulting in the limiting of information which can reasonably be displayed. Accordingly frequent replacement of the tags, associated power supplies, display facilities, etc, is the result.

In an effort to expand the versatility and efficiency of tracking and inventory control of a variety of articles, products, etc. and as a result of the problems and disadvantages of the type set forth above, associated industries have moved forward. Resulting advancements in this field has yielded the development and utilization of radio frequency (RF) tags and their attendant systems. In general, RF tags are capable of retaining and transmitting a substantial amount of information, all of which is required for the expansive tracking, security and inventory control requirements associated with modern day industrial, transport and retail facilities.

More specifically, the RF tag systems are capable of receiving and storing information in a read/write application as well as being capable of sending and/or receiving data relating to product identification, status, location and overall control. However, known or conventional RF tagging systems are recognized as having at least one primary disadvantage associated with limited communication range. Accordingly, in order that transmission of signals to one or more tags is accomplished for purposes of activation and/or data communication, an appropriate exciter/reader would have to be positioned in very close proximity to the one or more tags involved in the monitoring system. Therefore, the versatility and practical applications of such systems are severely limited due at least to the proximity or range restrictions associated therewith. Efficient monitoring of articles during product delivery, transportation, material handling, security tracking and large scale storage may not be possible. As a result, radio frequency tag technology has not enjoyed wide spread use in many industrial applications associated with the commercial development of various products.

Based on the above, there are still significant disadvantages and problems associated with known tagging systems especially when considering the wide variety of industrial applications where such systems could be effectively implemented. Accordingly, there is a significant and long recognized need for an improved tracking and/or inventory control system. Such an improved system should be capable of 100% real time inventory control as well as detecting the existence, location and direction of movement of an item being monitored. A plurality of RF tags associated with such an improved system could be further structured to detect tampering, low battery power, unauthorized movement and/or removal of the tags from the articles or products being monitored.

Such an improved system could also be adapted, without significant structural or operative modification, for usage in a variety of different areas including large scale warehousing, transport, delivery, retail inventory, pricing and security, theft prevention, all without significant manual intervention. In addition, other unique and/or customized features can be associated with the tags, dependent on the customer/user applications and requirements.

Accordingly, an improved system using multi frequency tags with strategically placed readers, accomplishing activation and/or powering of certain ones of the plurality of tags utilizing a higher level of power signal and prescribed frequency range would increase the reading or transmission distance associated with the tags. Such an improved system would overcome the recognized problems and disadvantages associated with RF tag monitoring systems of the type set forth above.

SUMMARY OF THE INVENTION

This invention is directed to a real time total asset visibility system which in a practical application is manifested in a monitoring system for maintaining inventory control, on a real time basis, of a variety of articles and within a monitored locale. In addition, the monitoring system of the present invention is capable of locating, tracking, identifying, and in some cases communicating with personnel so as to better accomplish the aforementioned real time total asset visibility of an area or locale being monitored. For purposes of clarity, the terms “monitored locale” may assume a variety of different locations such as, but not limited to a warehouse, manufacturing or storage facility, transport and/or delivery vehicles, as well as a variety of retail facilities. In addition, the versatility of the monitoring system of the present invention can be used for inventory control as well as positional and movement tracking of various articles with minimal or no structural/operational modifications of the various operative components of which the system is comprised.

More specifically, the system of the present invention comprises a host controller which may be in the form of a computer/processor disposed in communicating relation at or remote from the locale being monitored. In addition, a reader assembly comprises, dependent upon the specific embodiment and practical application for which the system of the present invention is adapted, one or more readers. As will be explained in greater detail hereinafter, the reader assembly may comprise a variety of different types of readers structured to perform a variety of procedures for individually and collectively monitoring a plurality of radio frequency (RF) responsive tags. The tags are mounted on or otherwise directly associated with various objects or articles being monitored. It is of course understood that the objects or articles being monitored may of course vary greatly and are not limited to a specific class or category of objects, products, etc. Also the tags may be a part of or directly associated with “personnel badges” for the location, identification, etc, of numerous authorized personnel which have access to the monitored locale and/or the plurality of articles or objects stored within or passing into or out of the monitored locale.

It is also emphasized that the reader assembly may in certain applications comprise a plurality of readers disposed in a predetermined array throughout the locale being monitored, such as when such a plurality of readers are fixedly disposed within the locale. In other preferred embodiments of the subject monitoring system, as represented by various practical applications, the reader assembly may comprise a single reader or relatively few readers. In this latter application and by way of example only, the reader assembly may comprise one or more mobile or handheld readers which are movable about the monitored locale. The mobile/handheld readers thereby communicate with the plurality of tags for purposes of establishing the existence and/or identification of the various articles associated with the tags.

The plurality of tags may also vary in structure and function based on their intended operation and the practical application to which they are applied. In the various preferred embodiments of the present invention a common operative characteristic of at least some of the plurality of tags is the ability to establish uni-directional communication or transmission to the reader assembly. Further, each of the tags is pre-programmed to include identification or other pertinent data which enables the user or operator to determine the status of the plurality of articles. As a generally descriptive term, the status of a monitored article may comprise the determination of its existence, location, direction of travel, removal, etc. dependent on the requirements of the customer or user of the subject monitoring or tracking system.

By way of example, in its simplest form, one or more of the tags defining the tag assembly comprise a passive tag characterized by not having a self-contained power supply associated therewith. Moreover, the passive tags are powered by being exposed to and/or maintained within an electric field or exposed to an electric signal of a predetermined first frequency. Once powered and activated, identification and/or pertinent data relating to inventory control and/or tracking is transmitted from the various passive tags (as well as the active tags to be described hereinafter) to an appropriate one or more readers servicing the monitored locale. Once received, the data transmitted from the plurality of tags is then transmitted by the reader assembly to the host controller/processor. The data is further processed by the host controller as required to maintain the desired inventory and/or tracking controls. As will also be explained in greater detail hereinafter, communication or transmission from the tags to the reader assembly occurs at a second frequency, which differs from the aforementioned first frequency or activation and/or power-up frequency.

Other structural and operative features of the tag assembly, are the ability of both a passive tag and an active tag to be programmed or re-programmed with new data in order that individual tags or a plurality of tags are representative of and may display most current data relating to the monitored or tracked products, materials, personnel, etc. As will be more evident hereinafter, such reprogramming and/or initial programming may be accomplished as the one or more tags are exposed to a generated field or signal from a fixed reader or from a hand held reader.

The tag assembly may also include one or more active tags which are distinguishable from the aforementioned passive tags by including a self-contained power source. As such, the active tags are pre-programmed to periodically transmit, on a pre-scheduled time basis, identification data or other appropriate information to one or more of the readers associated with the locale being monitored. Such active tags further include power supply detection capabilities which will communicate to the reader assembly the existence of a failing battery or a depleted power source. Both the passive and active tags are also structured to include numerous other operative features including tamper switches and locking devices particularly, but not exclusively, adapted for use in retail environments.

Further, both the passive and active tags may have common operative features such as multi-frequency capabilities wherein the activation or power-up field or signal is generated at the aforementioned first frequency and communication between the tag and the reader, either in a uni-directional or bi-directional mode, occurs at a second, differing frequency. The existence of the multi-frequency capabilities of the various tags enhances the range or proximity in which communication, activation, power-up, etc, may occur.

More specifically, FCC regulations prohibit the generation or transmission of pulsed signals, for example between a reader and a tag, except when licensing requirements are met. However FCC regulations do allow for the generation of fields/signals of certain frequencies, having pre-established band parameters, to be transmitted or generated at increased field strengths. Therefore, establishing a field strength of “unlimited radiated energy” within the frequency parameters specified is permitted. In other words, increased power can be utilized within certain specified frequency ranges, including 13.56 MHz. to increase the range in which the tags of a monitoring system can be detected, activated, powered-up, etc. without violating FCC regulations. Accordingly, activation signals or the establishment of electric fields for the activation or “wake-up” and/or “power-up” of one or a plurality of RF responsive tags can be accomplished using increased field strengths as long as no human exposure hazards are involved. Therefore, utilizing the aforementioned first frequency in the frequency range of 13.56 MHz. allows for the activation and/or powering (such as in passive tags) at a much higher energy level so as to increase the read distance and/or proximity range to at least approximately 12 to 15 feet without violating any regulatory codes. It is emphasized that while the aforementioned first frequency, in the frequency range of 13.56 MHz may be preferred due to the ability to use the higher energy level and thereby increase the read distance, other frequencies can be utilized to activate or power the tags, wherein such frequency may be in the range of 433 MHz.

The aforementioned multi-frequency capabilities of the various types of tags (both active and passive) in the monitoring system of the present invention further provides for data transmission or communication between the tags and the reader assembly at a second frequency, which differs from the aforementioned first frequency. Further such data transmission normally occurs on a periodic pulsed basis, at pre-scheduled times, rather than as a continuously generated, high strength field or signal, at which the first frequency normally occurs. Also, in certain preferred embodiments to be described hereinafter, one or more of the plurality of tags are structured for asynchronous transmissions, at the second communication frequency, to the reader or host controller.

As set forth above, the various embodiments of the present invention may further comprise a tracking system demonstrating certain control and tracking abilities. More specifically, the reader assembly may include at least one control reader and/or at least one tracking reader. Accordingly, at least some of the plurality of tags comprising operative components of the system are associated with a variety of objects or articles, and are specifically mounted on or connected thereto so as to move therewith. Therefore the objects or articles with which the plurality of tags are associated can be effectively tracked on a real time basis. As such, at least one of the aforementioned control readers may be mounted in predetermined relation to at least one, or more practically each, of the entrances/exits associated with the locale being monitored. Further, the control reader may be structured independently or in combination with the host controller to regulate specific observation facilities in order to allow real time viewing and/or recording or certain areas such as, but not limited to the entrance/exits or portals of the monitored locale. Such observation facilities can include cameras, display monitors, recorders and/or other video facilities capable of accomplishing and storing activities or events within a predetermined portion of the locale being monitored.

Operation and control of the aforementioned observation facilities may further include the monitoring of one or more individuals, products, etc. As such, a reader can find the location of individual tags or a plurality/group of tags and, when located, send a signal to a correspondingly located camera or other observation facilities so as to monitor or track the one or more tags which have been located, as well as the personnel or products associated therewith. Further, whether or not directly associated with specific observation facilities such as cameras, monitors, etc. the system can also wake-up individual ones or all of a predetermined plurality of tags located within a specific area, such as a meeting room, classroom, seminar area, etc. In doing so, the individuals in attendance at a seminar, class, meeting, etc. can be quickly and effectively established, assuming the attending personnel have an appropriate tag in their possession.

In addition, the aforementioned one or more tracking readers are structured to receive status data which is communicated to the host controller. The host controller, independently or in combination with the one or more tracking readers can determine position parameters relating to one or more of the plurality of tags being currently monitored or tracked. Such position parameters can also, in certain embodiments of the present invention, be considered part of tag status data transmitted from the tags to the various readers of the reader assembly. As such, the tags status data may include tag identification and/or position history as to where a particular object, article, etc. is or should be located within the monitored locale. Further structural capabilities of the host controller and/or the tracking reader include determination of the direction of movement or travel of one or more of the plurality of tags being currently monitored, wherein such information can also be included within or defined by the aforementioned position parameters.

It should be further noted that the “wake-up” field can be enabled by motion sensors, optical sensors, and similarly functional operational sensors having appropriate capabilities. Once activated, the one or more tags within the wake-up field will generate the identification or address of the individual tags, plus an appropriate reader address. This information allows operating personnel to identify and determine the location of any one tag or plurality of tags, at the time of wake-up or activation.

As described throughout, the utilization of at least some of the various preferred embodiments of the present invention involves the generation of a field signal or activating signal, to which the various tags are responsive to establish activation, wake-up tracking, and/or communication links. Typically and in at least some of the preferred embodiments, the field or activating signals are generated by the reader assemblies. However, in use the present invention also contemplates the use of a field generator for establishing such signal generation, wherein a field generator can be combined with a single reader or with each of the plurality of readers. Alternatively, the field generator or other facility for generating the field or activating signal can be operatively maintained separately and independent of any one of the reader assemblies. Also, the independent field generating facility can have its own address which can be linked to a single reader address. Yet another alternative embodiment would be the provision of several field generators linked to a single reader. Also, the field generator can be independently powered such as by a 12 volt DC transformer or by means of a contained battery source.

Yet another preferred embodiment of the present invention includes a functional variation of the subject monitoring system which is adapted to perform monitoring functions on any of a variety of different objects for purposes of monitoring location or tracking, tampering and at least one predetermined characteristic of the object. As set forth in greater detail hereinafter, the at least one predetermined monitored characteristic may comprise temperature, wherein the object being monitored is “temperature sensitive”. In addition, the monitored object may be animate or inanimate, wherein an inanimate object may include, but is not limited to, a container of temperature-sensitive fluid, such as a blood container. As is well known, blood must be maintained within a required temperature range during storage and/or transport. Similarly, and as set forth above, the monitoring system of the present invention may be used to monitor animate objects such as, but not limited to, medical patients. Typically a patient, or other individual under medical care, needs to have his/her temperature closely scrutinized. Also, it may be necessary under a variety of circumstances to the general proximity and/or more precise location closely monitored. Moreover, in order to maintain accurate and reliable monitoring procedures the tampering of the attendant monitoring facilities must be quickly determined, in order to prevent unauthorized or inadvertent removal thereof from the object being monitored.

Additionally, in this preferred embodiment(s) the monitoring system includes at least one RF tag, but more practically a plurality of such monitoring tags. Each of the one or more tags are mounted on, connected to or otherwise associated with the various animate or inanimate objects being monitored. Additional structural and operational features of the tag include the provision of a program application cooperatively structured for communication with a reader assembly and through the reader assembly to a host controller. Therefore, two-way communication is established between the monitoring tag and the host controller for purposes of regulating the operational characteristics of the tag during the monitoring procedure.

One such additional operating characteristic is the inclusion of a memory or data storage facility contained within the monitoring tag which may include data relating to the object including the object history, such as whether the object is animate or inanimate. Further, the program application is cooperatively structured to receive programming communication or signals which regulate a probe structure, such as a temperature probe, a pressure sensing probe, a vibration sensing probe, a motion sensing probe, etc. Programming regulation or control of the probe may be in the form of calibration thereof so as to adjust the range or parameters to be monitored in terms of the intended, relative state of the object being monitored.

Cooperative structuring between the RF tag and the reader assembly and there through to the host controller is similar or substantially equivalent to the communication links described herein with regard to the other preferred embodiments of the present invention. In its various forms, the tag of this preferred embodiment communicates with the reader at least upon a determination of a non-compliant status of the at least one predetermined characteristic of the object being monitored. Additional communication modes can be utilized which include the status of the predetermined characteristic being monitored and communicated by the tag continuously on a periodic basis over a predetermined period of time, rather than establishing communication only when a non-compliant condition exists.

A tracking assembly is also associated with this preferred embodiment of the present invention wherein communication leading to the establishment of location parameters of the tag and associated object being monitored can be accomplished by RF communication and/or GPS facilities and capabilities associated with the tag, the reader assembly and the host controller. Utilizing GPS capabilities, tracking and location of the object being monitored can be more effectively accomplished over a wider range, while RF communication capabilities are still applicable and accurately functional as set forth in detail herein. This preferred embodiment of the present invention further includes tamper resistant and/or indication facilities, as set forth above. Such tamper indicating capabilities include, but are not limited to, the accidental or unauthorized failure of circuitry associated with the operation of the monitoring tag, or more specifically with an attachment assembly for removably or fixedly securing the tag to the animate or inanimate object being monitored.

Moreover, in yet another embodiment, the tag can be effectively positioned at an object being monitored, with the reader only coming into communicative proximity at certain times. In such an embodiment, such as for monitoring conditions at a specific location, such as in a tunnel or other facility, periodic checks can be established merely by passing the reader into or through that communicative proximity so as to identify a compliant or non-compliant state at the tag, detect specific details regarding the current state at the tag, and/or collect stored data maintained at the tag regarding the state over a period of time.

These and other objects, features and advantages of the present invention will become clearer when the drawings as well as the detailed description are taken into consideration.

BRIEF DESCRIPTION OF THE DRAWINGS

For a fuller understanding of the nature of the present invention, reference should be had to the following detailed description taken in connection with the accompanying drawings in which:

FIG. 1 is a schematic representation of a preferred embodiment of the monitoring system of the present invention as demonstrated in one of a large number of possible practical applications.

FIG. 2 is a schematic representation of the interaction between various operative components of at least one preferred embodiment of the system of the present invention, including a host controller, reader assembly and tag assembly.

FIG. 2A is a schematic representation of the interaction between various operative components of another preferred embodiment of the system of the present invention.

FIG. 2B is a schematic representation of the interaction between various operative components of yet another preferred embodiment of the system of the present invention.

FIG. 3 is a schematic representation of the interaction between the various operative components of another preferred embodiment of the system of the present invention.

FIG. 4 is a schematic representation of the interaction between the various operative components of yet another preferred embodiment of the system of the present invention.

FIG. 5 is a schematic representation of the interaction between the various operative components of yet another preferred embodiment of the system of the present invention.

FIG. 6 is a schematic representation of the operative components of at least one preferred embodiment of a reader associated with the reader assembly of the present invention.

FIG. 7 is a schematic representation of a programming station or assembly for programming one or more tags included within the monitoring system of the present invention.

FIG. 8 is a schematic representation of another preferred embodiment of a reader associated with the reader assembly of the present invention.

FIG. 9 is a schematic view showing details of various operative and structural variations of the tags utilized in one or more of the various preferred embodiments of the system of the present invention.

FIG. 10 is a schematic representation of yet another preferred embodiment of a tag structure of the monitoring system of the present invention.

FIG. 11 is a schematic, composite view of communication facilities associated with yet another preferred embodiment of the monitoring system of the present invention relating to GPS tracking.

FIG. 12 is a schematic view of an attachment assembly for securing the tag of the embodiment of FIGS. 10 and 11 to an animate object being monitored.

FIG. 13 is a perspective view of an inanimate object, in the form of a storage container of blood or other temperature sensitive fluid, being monitored.

FIG. 14 is a detailed view of an attachment assembly for securing the tag of the embodiment of FIG. 10 and/or 11 to the object of the embodiment of FIG. 13.

Like reference numerals refer to like parts throughout the several views of the drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

As shown in the accompanying Figures and as generally represented in FIG. 1, the present invention is directed to a real time total asset visibility system particularly, but not exclusively, adapted for maintaining effective inventory control as well as being capable of accomplishing efficient tracking of a plurality of articles or objects, including animate and inanimate objects, wherein the status of the various articles or objects can be determined on a real time basis. As used herein, the status of the various monitored articles is more specifically meant to describe the ability to determine the existence, location, identity, direction of movement, as well as the passage of the various articles to and from a monitored locale. However, at least one additional preferred embodiment is structured to also monitor the status of at least one predetermined characteristic of the object such as, but not limited to, temperature. The temperature status may be of particular importance in the monitoring of a medical patient or an inanimate object, such as a storage container of blood or other temperature sensitive material.

Accordingly, as disclosed in the various preferred embodiments of FIGS. 1 through 9, a monitored locale is generally indicated as 10 and may include a warehouse, storage facility, transportation depot, etc. It is emphasized that the locale being monitored may also include various industrial sites 11 where the articles are manufactured or processed and any of a number of various transportation vehicles such as ships generally indicated as 12, trucks generally indicated as 13, etc. Such vehicles may be associated with the transport and temporary storage of the monitored articles.

In addition, the monitoring system of the present invention includes one or more host controllers generally indicated as 14 which are disposed in communicating relation with anyone or all of the plurality of monitored locales 10 through 13. The host controller 14 may be in the form of a somewhat conventional PC, or other processor/computer facility 16 and is utilized to accomplish higher level processing in order to filter the data received from the remainder of the operative components of the monitoring system of the present invention and thereby maintain adequate inventory control and/or perform tracking procedures, as set forth above.

As also schematically represented in FIG. 1, communication between the various monitored locales 10 through 13 and the one or more host controllers 14 may occur by a variety of different relatively standard communication facilities. Such communication facilities may include, but are not limited to, wireless transmission, Internet access, hard wire connections, satellite or GPRS communication, etc. Moreover, the host controller can be located in close proximity to the monitored locale, such as a warehouse or like facility 10, or be disposed a fixed or variable remote distance therefrom in the case of transportation vehicles 12, 13, etc.

In addition to the host controller 14, the monitoring system of the present invention comprises a reader assembly which includes at least one, but dependent upon the specific preferred embodiment being utilized and the practical applications associated therewith, a plurality of readers. In the preferred embodiment of FIG. 1, the plurality of readers are generally indicated as 18 and are fixedly disposed in a predetermined array relative to the configuration of the locale 10 being monitored. More specifically, the plurality of readers 18 are disbursed throughout the monitored locale 10 so as to provide complete, real time communication with a plurality of tags 20 contained within the locale 10.

As shown the plurality of tags 20 are associated with a plurality of articles 22 which of course may be defined by any type of product, object, personnel identification badge, etc. The plurality of tags utilized in a specific user application may vary in structure, function and operation and, as will be described hereinafter, may be broadly classified as being operative in a passive mode (passive tags) or active mode (active tags). The passive and active tags are distinguishable from one another by the active tags including a self-contained power source such as a battery, which may or may not be rechargeable. The passive tags are absent any self contained power source. Further, both the active and passive tags are generically defined by micro-circuitry including a transmitter and/or transceiver as well as appropriate transmitting and/or receiving antennas. Customized integrated circuits (IC) could be adapted for specific customer or user applications as required and still be incorporated within the spirit and scope of the present invention.

The various categories of monitoring tags, being either passive or active, may also be structured to be at least uni-directional in terms of transmitting identification or other pertinent data therefrom to one or more readers defining a particular reader assembly. Alternatively, in at least one preferred embodiment of the monitoring system of the present invention, the tags include bi-directional communication capabilities, wherein data may be transmitted from the tag to the one or more readers and acknowledgment and other directive or informative signals may be directed from the one or more readers back to the tag.

Yet another structural and operative feature of the tag assembly of the present invention is the ability of at least some of the aforementioned tags to include multi-frequency capabilities. More specifically, a first frequency is utilized to activate either a passive or active tag, dependent upon the specific embodiment being practiced. Tag activation can be broadly defined as providing power to passive tags and/or serving to “wake-up” active or passive tags. Also, the recharging of the batteries included in the structure of the active tags can also be accomplished by exposing the active tags to a generated field or signal at the first frequency.

In compliance with FCC regulations the first frequency, preferably in the bandwidth of 13.56 MHz, is allowed to be generated at an increased field or signal strength which is sufficiently high to enhance the operative range between the tag and the reader or other activation facility serving to generate the activating field or signal. In accordance with FCC regulations establishing a field strength of “unlimited radiated energy” in the bandwidth parameters specified for certain frequencies (13.56 MHz.) is permitted absent any potential hazards associated with human exposure. The activating or operative proximity range can thereby be extended to approximately 12 to 15 feet without violating FCC regulations. It is emphasized, that the aforementioned and defined first frequency is preferably in the range the 13.56 MHz, because of the stated increase in operative proximity range, however, other frequencies could be used and defined as the first frequency. More specifically, a frequently range of 433 MHz could also be used as a first frequency.

In addition, the multi-frequency capabilities of certain ones of the plurality of tags may also be defined by data transmission or communication from the tag to the reader assembly at a second frequency which differs from the first frequency. The second frequency is preferably, but not exclusively, in the 915 MHz, 868 MHz or 433 MHz frequency range. Accordingly, data is transmitted between the plurality of tags at the designated second frequency on a repetitive pulsed basis rather than maintaining a continuous field or constant signal generation at the lower 13.56 MHz (or 433 MHz) which preferably defines the first frequency.

It is to be understood that not all of the plurality of tags, either passive or active, are structured for intended exposure to the first frequency range in order to accomplish activation. More specifically, and with reference to the embodiments of FIGS. 1 and 2, the one or more readers 18 are disposed in a predetermined proximity relative to a plurality of tags 20 within the monitored locale 10. Each of the tags 20 are operative in an active mode and are structured for uni-directional transmission. As such, each of the tags 20 is normally maintained in “sleep mode” for certain pre-programmed periods of time. After the time period has expired, the tag will automatically go into its unique anti-collision skim and start transmitting appropriate identification or like data several times to make sure that one or more of the plurality of readers 18 will receive such transmitted data. After the data is transmitted several times, the tag will then automatically reset itself and will again go into a sleep mode until a predetermined or pre-programmed time has again expired. Transmission will then be repeated. Further, the plurality of tags can have the same transmission time or different pre-scheduled transmission times.

Clearly, the time period that the tag goes to “sleep” varies based on customer requirements. However, additional structural and operative features associated with the RF tags, will cause the tags to start communication or transmission to the reader assembly asynchronously based on the occurrence of certain events. By way of example, asynchronous transmission of a tag may occur, in certain preferred embodiments of the present invention, when the tag wakes-up because it is passing through a certain electronic field or because it receives a stand-by command by receiving pulses of a specified frequency from the reader. Alternatively, the tag will wake-up because it went into a programming mode as will be explained with reference to the embodiment of FIG. 7. The tag may also wake-up because of the existence of a tampering detector or because of a low power detection of the self-contained power source associated with active tags. As also to be described in greater detail hereinafter, the tags may wake-up or operatively communicate with a hand held reader at a preferred 13.56 MHz frequency (or 433 MHz).

Two categories of active tags are distinguishable, at least in part, as being either directional or uni-directional in their intended transmission capabilities. The bi-directional active tag, after transmitting its tag identification or other appropriate data to the reader may expect to receive an acknowledgment or other directive signal from the host controller through the reader assembly. If the bi-directional active tag receives no response signal or an un-acceptable acknowledgment or directive signal it reverts back to its anti-collision skim and continuously sends transmitted data until it receives an acceptable acknowledgment signal from the host. The bi-directional active tag will then re-set its timer in the conventional fashion, as with the uni-directional active tag, and it will go into a sleep mode until the pre-programmed time expires. Upon expiration of the preprogrammed time transmission of the ID or other appropriate data will be repeated. As with the uni-directional active tag, the bi-directional active tag will start to communicate with the reader on an asynchronous basis upon the occurrence of specific events, as set forth above.

In order to better achieve real time inventory control and facilitate desired tracking procedures, concurrent communication of the plurality of tags with the reader assembly is accomplished through the inclusion of an anti-collision protocol. More specifically, a multi-tag algorithm is integrated into the tag assembly and/or reader assembly which is operative to allow the concurrent transmission by and reading of data from a plurality tags while encountering minimal if any meaningful interference. Accordingly, upon being activated each of the plurality of tags assumes an anti-collision skim prior to pre-scheduled and/or asynchronous communication.

The reader assembly of the present invention serves as a communication link between the plurality of tags and host controller 14. As such, the reader assembly may include one or more readers, dependent upon the specific practical application and the preferred embodiment associated therewith, wherein various types of readers may be defined as part of the reader assembly. Preferably, common structural and operational features are included in each of the various readers, regardless of their type or category. Further, each of the various types of readers has a dynamic addressing capability as it powers-up. In doing so, the individual reader will send a power-up command to inform the host controller 14 that it is alive and requesting a specific reader address. The host 14 will initiate the addressing of the reader and in performing this initialization process, a two way communication link is established there between as at 17 utilizing the second frequency range of the tags 20 or other appropriate frequency range. Further, the communication link 17 represents either a hard wire connection or wireless communication. It should also be noted that the reader address can be established automatically without having any addressing switches.

The reader assembly can include one or more fixed readers, such as readers 18 being fixedly disposed throughout the monitored locale 10. In this context, the term “fixed” is not necessarily meant to describe a permanent mounting in that the various readers 18 can be removed, repaired, replaced, etc. Further in the embodiment of FIGS. 1 and 2 the readers 18 may be powered by a conventional 110 or 220 power source and be connected thereto by being removably attached to a conventional light socket or by utilizing other means of attachment.

As set forth herein, at least one preferred embodiment of the system of the present invention may be more accurately described as a tracking system incorporating specific tracking and/or access control features which accomplishes not only the determination of the identity, location and other tag status of the various plurality of tags and objects associated therewith, but also facilitates the tracking of the movement, travel, replacement, etc. of the tags and associated objects within a predetermined locale. In addition, the authorized or unauthorized entry and existing of authorized and unauthorized personnel into and out of the locale being monitored as well as the entry or removal of any objects being transported by such authorized or unauthorized personnel can be regulated.

More specifically, the monitoring of activities around and through and access portal 100 can be established utilizing one or more control readers 104. It is of course recognized that one or more portals 100 may be associated with an area or predetermined locale being monitored. As such, one or more control readers 18′ may be provided in the tracking system of the present invention. In this preferred embodiment of the tracking system of the present invention, the control reader 18′ includes a 915 megahertz or 868 megahertz transceiver that communicates with at least some or any one of the tags 20 entering within a predetermined range of the portal 100. The predetermined range may be established by the generation of an activating signal by the control reader 18′. The activating signal may be more specifically defined by an activating field generated preferably at the first frequency range of 13.56 mz. When any one of a plurality of tags 20 enters the activating field, it will in turn be activated and subsequently transmit tag status data to the associated reader 18′, preferably on a repeated basis. Such tag status data can include tag identification, location, as well as other pre-programmed information. If the one or more tags 20 associated with various objects 22 and/or personnel 23 remain within the activating field the repeated transmission of the tag status data will eventually cease after a predetermined time period. The tags 20 will then assume a sleep mode until a predetermined time has elapsed. If after the predetermined time has elapsed and if the tag is still within the activating field, the tag status data will again be transmitted to the control reader 18′ or other associated readers 18 on a repeated basis. If the tag is removed from the activating field, it will then assume its original sleep mode until reactivated by an activating signal generated by an appropriate reader 18, 18′ of the reader assembly.

Further, each of the one or more control readers 18′ is structured to trigger an output relay so as to control opening or closing of the access portal 100 with which it is associated. Also, an observation assembly or facility 104 is preferably located in an observing location relative to the vicinity surrounding the access portal so as to view, on a real time basis, and record any activities being conducted in the vicinity of the access portal 100. Such activities may include the attempted ingress or egress relative to the interior of the predetermined locale being monitored and tracked. The observation facility 104 therefore may include a variety of video facilities capable of accomplishing real time and/or stored recordings of video observation of the various activities associated with the access portal 100.

By way of example only if an individual as at 23 is unauthorized to enter the predetermined locale being monitored and/or is carrying objects 22 that are not authorized to pass through the portal 100, operative communication will be transmitted from either the control reader 18′ directly and/or the host controller 14 by means of appropriate facilities such as computer/processor 16. Such signals will prevent the passage of the individual 23 and/or object 22 through the portal 100 if authorization is not present. Concurrently, the observation facilities 104 will be directed to the portal 100. Other display and/or communication facilities may be appropriately positioned at either the host controller 14 and/or an association with any operator or individual further regulating control of entrance or exiting of the predetermined locale.

The control reader 18′, upon receiving tag status transmission from one or more tags 20 will transfer the information to the host controller 14. The host controller 14 can respond to the control reader 18′ to the effect of validating or authorizing movement or travel of personnel 23 and/or objects 22. Similarly, the authorization of individuals 23 and/or objects 22 can be invalidated or not recognized thereby preventing ingress or egress through the portal 100.

With reference to FIG. 2A, each of the one or more control readers 18′ preferably includes a data base having information stored therein relating to recent tag activities including identification, position, location, etc. If the control reader 18′ finds that sufficient data is stored within the data base 19, communication to establish the validity or invalidity of the authorization of personnel 23 or objects 22 need not be made. Therefore, each of the one or more control readers 18′ may determine the validity or authorization of travel or positioning of personnel 23 and/or objects 22 either through communication with and input from the host controller 14 or independently thereof through accessing information in data base 19. As set forth above the control reader 18′ will communicate to the host controller 14 through RS232 communication configuration or wireless communication at 2450 Megahertz or the tag frequency.

With reference to FIG. 2B, the tracking system embodiment of the present invention may also include one or more tracking readers 18″ associated with the reader assembly of the present invention. The tracking reader 18″ includes a 915 Megahertz or 868 Megahertz transceiver that communicates with the tag. If there is a tag 20 passing through the activation field established by the one or more tracking readers 18″, the tag will transmit tag status data at least including tag identification and/or travel activity or history of the personnel 23 or object 22 associated with a given tag 20. This tag status will be then transmitted from the tracking reader 18″ to the host controller 14. The host controller will analyze the tag status transmitted data at least in terms of determining the previous location of the personnel 23 or objects 22 with which one or more tags are associated. Subsequent to appropriate analysis, a decision will then be made relating to position parameters of the individuals tags associated with the objects 22 of personnel 22. Such position parameters can include, as set forth above, not only tag identification information but appropriate information determinative of tag movement including direction of movement and/or location or custom mated destination.

With reference to FIG. 3, another preferred embodiment of the present invention comprises the reader assembly including at least one but preferably a plurality of shelf readers 30. The shelf readers 30 are at least partially distinguishable from the warehouse or fixed readers 18 as set forth in greater detail hereinafter. As such, each of the shelf readers 30 include a 915 MHz., 868 MHz or 433 MHz. transceiver that communicates with the tag. The tag assembly comprises a plurality of tags 32 associated with a plurality of articles being monitored (not shown for purposes of clarity), wherein the tags 32 are active and include multi-frequency, bi-directional capabilities. As such, the one or more readers 30 generates and transmits an activation signal at the aforementioned first frequency of 13.56 MHz. or 433 MHz. for purposes of tag activation or wake-up. Upon being activated, the tags 32 will send the appropriate data transmissions to the one or more shelf readers 30. The readers 30 will send the transmitted data received from the tags to the host controller 14 for further processing. Communication between the readers 30 and the host controller 14 will occur by either RS232, wireless communications at 2450 MHz., or the specific tag communication frequency, as set forth above.

The physical characteristics of the shelf readers 30 may of course vary but such readers 30 typically include 13.56 MHz. or 433 MHz. antennas mounted on or within an appropriate casing that can be attached to or otherwise associated with shelving or other facilities on which the various articles being monitored are stored, displayed, etc. It should be apparent, that the particular preferred embodiment incorporating the shelf readers 30 and the cooperatively structured bi-directional, multi-frequency capable tags 32 is readily adaptable for retail outlets or like retail facilities.

In another preferred embodiment schematically represented in FIG. 4, the monitored locale comprises a vehicle 12 and/or 13. As such, the reader assembly associated therewith comprises one or more vehicle readers 34 disposed in communicating relation with a plurality of tags 36 defining the attendant tag assembly. As with the previous preferred embodiments, the one or more vehicle readers 34 include a 915 MHz., 868 MHz. or 433 MHz transceiver which communicates with the plurality of tags 36. The tags are associated with a plurality of shipping boxes, containers or directly with the articles themselves. As the tags 36 are self activated from their sleep mode, ID or other appropriate data is transmitted to the one or more vehicle readers 34. The vehicle readers 34 are structured to have the capability of communicating this transmitted data from tags 36 to the host controller 14.

The one or more vehicle readers 36 can be powered by a variety of substantially conventional power sources such as one or more batteries or any other appropriate power source which may be associated with the vehicles 12, 13, etc. Moreover, when the monitored locale is a transport vehicle including a truck 13, A tracking procedure may be incorporated within this preferred embodiment of the subject monitoring system. More specifically, when any box, shipping container or article associated with one of the tags 36 passes into or out of the truck 13, the tags 36 will be automatically activated on an asynchronous basis and send tag ID or other appropriate data to the one or more readers 34. In addition, at least some of the tags which are communicative with the vehicle reader can include information relating to the vehicle and/or driver identification. Accordingly, as the vehicle approaches a given area, security or other personnel can check the tag identification information with vehicle documents, driver's license, etc. Appropriate information will be transmitted to the host controller 14 for processing. Therefore, the loading of the boxes, articles, etc. with the tags 36 mounted thereon will allow the inventory information to be coordinated with various shipping invoices or other documentation to determine the existence or non-existence of a discrepancy there between. Communication between the readers 34 and host controller 14 can be accomplished by a variety of substantially conventional communication facilities.

Still another preferred embodiment of the present invention is schematically represented in FIG. 5. As schematically represented therein, the reader assembly includes at least one or alternatively a plurality of mobile or handheld readers 38. The mobile readers 38 are communicative with the host controller 14 by an appropriate communication link 17 as described above. As will be apparent, the mobile or handheld reader 38 is particularly adaptable for inventory control in the application of a variety of different retail facilities. As with the previously described readers, the handheld/mobile reader 38 has a 915 MHz., 868 MHz., or 433 MHz. transceiver that communicates with the plurality of tags 40. The handheld/mobile reader 38 will transmit an activating signal at the aforementioned first frequency of preferably 13.56 MHz. or 433 MHz. By manual control of certain control facilities or hardware associated directly with the mobile reader 38. As a result, at least one, but preferably all of the plurality of tags will be exposed to the generated field at the first frequency and will wake-up and transmit (at the second frequency) ID and/or other appropriate data to the handheld/mobile reader 38. Also, the mobile reader 38 has the ability to “write” appropriate information into a storage facility associated with the various tags for subsequent accessing.

In certain instances associated with the intended inventory control procedure the identifying of a specific tag location, existence, identity, etc. may be required. In doing so, the reader 38 will determine the strength of the transmitted signal from a designated or searched for tag 40. As the handheld/mobile reader 38 enters into a closer proximity to a specified tag as at 40′, the transmitted signal from tag 40′ will of course increase until the reader 38 narrows the proximity range down to the specific tag 40′. The handheld reader 38 may also include specific visual display facilities which will be explained in greater detail with reference to FIG. 9 but which generally may be in the form of an LCD display.

The versatility of the monitoring system of the present invention is further evidenced by the schematically represented preferred embodiment of FIG. 6. In this embodiment a reader module 42 can be embedded in a bar code reader generally indicated as 44. A bar code scanner or other facility 46 is operative to scan or detect certain bar codes on tags and/or labels 48. The bar code data is communicated to the reader module 42 which serves to re-transmit the bar code data to the host controller 14 for further processing. The reader module 42 may also be operatively structured within the overall bar code reader 44 to independently read appropriately configured tags as at 48′ independent of any bar code display thereon. As set forth above the communication link 17′ between the reader module 42 and the host controller 14 is bi-directional and in this context host controller 14 may send an acknowledgment signal after receiving any appropriate data from the reader module 42.

At least one preferred embodiment of the monitoring system of the present invention includes the provision of programming assembly or station generally indicated as 50. Each of a plurality of tags, regardless of their intended performance and operative content and indicated in FIG. 7 as 20, 32, 40 and 48, etc. are structured to be programmed and/or re-programmed by programming assembly 50. The programming assembly 50 will use the same frequency that powers the tag (first frequency) but preferably at a much lower field strength in order to comply with specific FCC regulations. Therefore, the proximity “write” range between the programming assembly 50 and the one or more tags 20, 32, 40, 48, etc. being reprogrammed will be significantly shorter than that available when normally utilizing the first frequency at high field strengths. Acknowledgment of re-programming will be observed through an appropriate acknowledgment signal generated by the plurality of tags at the normal communication frequency (second frequency). The programming assembly 50 and the various structures of the individual tags provide for the programming or reprogramming of the tags individually or collectively. The reprogramming procedure is accomplished in order to supply one or more tags with the most current data, such as a change in data or information. Further, the programming assembly 50 can be broadly or generally defined, in at least one embodiment of the present invention, as a fixed or permanent reader and/or a hand held reader, as previously described.

Further structural features preferably, but not necessarily, common to all of the plurality of tags 20, 32, 40, 48, etc. is the inclusion of a tamper switch or detector. As a result an attempt to remove the tag from the article being monitored or otherwise disassociate it therefrom will result in its automatic activation or wake-up. The generation of a warning or alarm signal from the tag to the host or an appropriate reader will result in the signaling of the host controller 14. Similarly, for the various active tags incorporating a self contained power source, a low battery detector 54 can also be incorporated in the various active tags so as to detect a failure or a predetermined low energy output from the self contained power source. Similar automatic activation and alarm signaling of the host, preferably through an appropriate reader will also be accomplished.

Yet another device associated with at least some of the plurality of tags is the inclusion of a mounting or lock device or assembly 56. Such lock device 56 will be particularly adaptable for use in a retail facility or environment. As such, the tag 20, 32, 40, 48 etc. will be connected to a product displayed or presented for sale (and/or stored items). The lock device will prevent the tag from becoming detached from the article being monitored unless it is exposed to an electric field or signal, preferably within the first frequency range of 13.56 MHz or 433 MHz. This field will cause activation or wake-up of the tag and the tag will send ID or other appropriate data to one or more readers of an associated reader assembly. If the transmitted data is valid, recognizing that the customer is buying the item, then the reader will send a command to the lock device 56 allowing the associated tag to be removed from the article being sold prior to it leaving the retail facility.

One or more of the preferred embodiments of the present invention may incorporate one or more readers 38′ incorporating a display facility 60. A typical practical application of the leader 38′ having a display facility 60 is that used in the mobile or handheld computer 38 in the preferred embodiment of FIG. 5. As such, the reader 38, 38′ has a 2450 MHz. or 915 MHz., 868 MHz. or 433 MHz. transceiver that communicates with the host controller 14. The reader 38, 38′ is connected directly to any size LCD or other appropriate display 60. The display 60 will be used for displaying any information about the monitored article, transporting carrier, box, contents or any other information that the customer/user would like to display in maintaining an inventory control and/or tracking procedure as set forth above. The versatility of at least one embodiment of the present invention is further demonstrated by the display 60 being used to indicate price information in a retail establishment such as, but not limited to, a grocery store or the like, wherein the quantity and/or volume of products is extensive. A central computer can send a command to an appropriate reader to wake-up individual ones or an entire group of tags. The updated or current data, such as price information or any other information of the type that need be displayed can be transferred to the tag. The display 60 will thereafter display the new information, when appropriate, in an immediate fashion.

Common to at least some of the preferred embodiments described above is the inclusion of certain “repeater capabilities” within one or more of the individual readers associated with any reader assembly. As such, a repeater/reader serves as an amplifier and, in addition to processing any transmitted data in the context of the normal reader performance characteristics, will facilitate transmission of such data between readers or from the readers to the host controller 14. Typically, a repeater/reader is positioned and/or utilized when a conventional reader without repeater capabilities is located a distance from the host controller or other readers which derogatorily affects the efficient or reliable transmission of communication signals there between.

In addition to the above the various readers, tags, etc. may be provided with various antenna structures operative to form their intended communication functions. Such various antenna structures may include a high frequency reader antenna, transmitter antenna, shelf antenna (short range), communication antenna, etc.

As described throughout, the various preferred embodiments of the present invention include the generation of a field signal or activating signal, to which the various tags are responsive to establish activation, wake-up tracking, and/or communication links. Typically and in at least some of the preferred embodiments, the field or activating signals are generated by the different embodiments of the reader assemblies. Moreover, a practical application of the present invention may involve provision of a field generator for establishing such signal generation. The field generator can be combined with a single reader or with each of the plurality of readers. Alternatively, the field generator or other facility for generating the field or activating signal can be operatively maintained separately and independently of anyone or more of the reader assemblies. The independent field generating facility can have its own address that is linked to a single reader address. Yet another alternative embodiment would be the provision of several field generators linked to a single reader. Also, the field generator can be independently powered such as by a 12 volts DC transformer or by means of contained battery.

As represented in FIGS. 10 through 14, the monitoring system of the present invention comprises yet additional preferred embodiments. More specifically as with the previously described embodiments, the monitoring system includes one or more host controllers generally indicated as 214, each of which includes a conventional PC or other processor facility 216. The processor/computer facility 216 is structurally and operationally configured to accomplish a sufficiently high level of processing in order to filter data received from a remainder of the operative components of the monitoring system including one or more readers 218 and/or satellite communication generally indicated as 220 which may be associated with a ground positioning system (GPS).

This preferred embodiment of the monitoring system of the present invention is operationally and structurally modified from the previous embodiments at least to the extent of including the ability to monitor at least one predetermined characteristic of an object. In addition, the object being monitored can be an animate object such as an individual or patient within a healthcare facilities and/or an inanimate object such as, but not limited to, a storage container 270. In the latter category, the inanimate object would be such as to demonstrate the predetermined characteristic being monitored. By way of example, the at least one predetermined characteristic being monitored could be temperature. As such, the temperature of an individual could be continuously monitored so as to maintain the temperature within predetermined parameters or a predetermined temperature range. Similarly, an inanimate object being monitored for temperature could include the storage container 270 used to store and/or transport blood or other temperature-sensitive fluid prior to use.

With primary reference to FIG. 10, this preferred embodiment of the monitoring system, as with the other embodiments described above, includes an RF tag generally indicated as 222, which is preferably active by including a self contained power source. As further represented, the tag includes a probe structure 224 which in use would be in direct contact or otherwise disposed in appropriate proximity to the monitored object for determining a state thereof. As is well known, the structural and operational features of the probe 224 could assume a variety of different embodiments appropriately structured to be used in combination with the tag 222 and the various other applications or facilities associated therewith. For example, the probe could be utilized to monitor a temperature or temperature range of or near the object, or could be used to monitor a pressure state, vibration state and/or motion state at or of the object being monitored. In this regard, it is noted that although a variety of different probe structures 224 could be utilized, including any combination of different types of probes, for purposes of clarity the following description will refer to one of the various preferred embodiments, namely the temperature sensing probe.

Additional versatility to the probe structure 224 is provided by means of a program application 226. As such, the probe 224 may be directly programmed such as by communication with and between the reader 218 and/or the host controller 214. As with the previously described embodiments, the reader 218 and the one or more RF tags 222 are cooperatively structured to establish communication there between. Also, the reader will serve as a communication link between the one or more RF tags 222 and the host controller 214, wherein the host controller 214 provides programming facilities and more sophisticated processing, as indicated above.

Functioning, activation and programming of the probe 224 can be accomplished by wireless communication initially instigated from the host controller 214 through the reader 218. Moreover, the probe 224 may be programmed to include certain temperature ranges which are to be monitored. In the event the monitored temperature of the inanimate object or animate object fall outside the predetermined temperature range, appropriate alarm facilities, such as that associated with the processor facility 216 will be activated thereby providing adequate indication as to a non-compliant status of the temperature or other predetermined characteristic of the object being monitored. Further visual or audible alarm facilities may be incorporated directly into the tag 222, as at 225.

Another feature associated with the cooperatively structured and operable program application 226 and probe 224 is a calibration capability 228 which may be controlled or regulated by the program application 226. Specifically, the calibration application functions to assure the accuracy of the temperature characteristic being monitored. Required accuracy is facilitated by matching or aligning the monitored temperature parameters of the probe 224 and the object which the probe is monitoring. As such, the calibration facility will be at least partially dependent upon the relative location of the probe on the patient/individual or inanimate object being monitored. Further with regard to FIG. 10, the one or more tags 222 may also include memory capabilities 230. The memory capabilities 230 may be accessed from a remote location, such as by the host controller 214 through the program application 226 via communication with the tag 222 by means of the reader 218. As such, the memory facility 230 can store significant or meaningful object data such as the history of the patient, the time storage began on an inanimate object, the required temperature parameters, the length of time of the monitoring period, etc.

In addition, the one or more tags 222, the one or more corresponding readers 218 and the one or more host controllers 214 can be cooperatively structured such that an alarm or signal is generated by the tag 222 at least when a non-compliant status of the temperature or other predetermined characteristic has been determined by the probe 224. As such, the reader assembly is structured to communicate with the host controller at least when a non-compliant status of the object has been determined so that appropriate, corrective action may be undertaken.

Alternatively, the tag 222 can communicate with the host controller, through the reader 218 substantially continuously, but on a periodic basis at prescheduled times over a predetermined time period as programmed. By means of this latter mode of communication, a signaling of the host controller 214 by the tag 222 indicating a non-compliant status of the characteristic being monitored will result in further action being taken. Yet another possibility is anticipated by the monitoring system of the present invention in that a failure to generate a communicating signal between the tag 222 and the host controller 214, via the reader 218, in conformance with the periodic, prescheduled basis would also be determinative of an alarm activation indicating malfunction of the tag 222 and a possible determination that a non-compliant status of the monitored characteristic is present.

With reference to FIG. 11, other features of this preferred embodiment of the present invention include the ability to track and/or locate the object being monitored. More specifically, the tag 222′ includes a tracking assembly 232 which is structured to communicate to the host controller 214, such as through the reader 218 utilizing the RF frequency format as generally described above. In the alternative, the tag 222 or 222′ may include GPS capabilities as at 234 for efficiently determining the specific location of the object being monitored, whether that object be animate or inanimate as described above.

In operation, anytime the exact location of the object is required to be determined, a command signal can be sent to the tag 222′ from the host controller 214 through the reader 218 as also described above. The initial communication may be in the form of an activating signal indicating that the tracking assembly 232 is required to activate the GPS capability 234. Once activated, the tag 222′ will be capable of direct determinative communication between an appropriate satellite assembly 220. A precise location of the object being monitored can then be determined by communication between the satellite 220 and the host controller 214 and/or intercepted communication with the reader 218.

Additional features of this embodiment of the present invention are represented schematically in FIGS. 12-14. More specifically and depending at least in part on the object being monitored, the tag 222 or 222′ may be removably or fixedly attached to the monitored object. FIG. 12 is a schematic representation of one embodiment of an attachment assembly generally indicated as 240 preferably, but not exclusively, in the form of a bracelet or like elongated flexible material strap capable of being secured about the wrist, arm, leg, etc. of an individual, such as a patient. As such, the mounting assembly 240 is removably secured to the patient and as such provides no inordinate discomfort or inconvenience.

The attachment assembly 240 has a generally elongated configuration including a main segment 242, a connecting segment 244 and a connector assembly at least partially indicated as 246. While being schematically represented, the connector assembly 246 may include a conductive, outwardly extending finger or protrusion 247, which is intended to pass through any one of the plurality of apertures 248 extending along the length of the main or primary segment 242. As represented, the removable attachment assembly 240 also includes the circuitry structure including a plurality of conductors 249 interconnecting the plurality of apertures 248 and cooperatively structured therewith so as to electrically engage the finger 247 as it passes through one of the apertures 248. A conductive circuit is thereby completed and the main segment 242 is disposed in a loop dimensioned and configured to surround and be removably connected to a corresponding portion of an individual's body. Once so positioned, the connecting segment 244 includes aperture 251 which also fits over a free end of the finger 247 in overlapping, locking engagement with the portion of the main strap segment 242 engaged by the finger 247. The circuitry 249 also includes additional conductive strands used to complete the circuit when the strap is in its closed, surrounding position as described above. Further, the circuitry associated with the attachment assembly 240 may also include an antenna array including a receiving antenna 253 and a transmitting antenna 255. This antenna array also defines a part of the completed circuitry when the attachment assembly 240 is in its interconnected position and secured about a portion of an individual or patient.

In addition, the removable attachment assembly 240, including the circuitry as described above, provides a tamper-resistant or tamper-indicating assembly or structure which will establish communication with or between an appropriate reader 218 and eventually to the host controller 214. In addition, a tag 222 or 222′ will be fixedly connected into the circuitry of the attachment assembly 240 through appropriate terminals 260, 261, 262, etc. Therefore, communication between the reader 218 and the tag assembled within the circuitry of the attachment assembly 240 may occur on a periodic basis over a continuous time period as indicated above or the tag may communicate with the host controller 214 through the reader 218 in the event of a non-compliant status with the temperature or other predetermined characteristic being monitored. The tamper-resistant facility is further structured to cause activation of an alarm 225 on the aforementioned tag 222, 222′ and/or the host controller 214 through the processor 216 upon removal of the tag from the circuitry or the failure of the circuitry itself.

Accordingly, one feature of the circuitry of the removable attachment assembly 240 is the formation of the conductive portions thereof from an electro-conductive coating or electro-conductive paint. Therefore, a breaking of any portion of the attachment assembly 240 will cause a break or failure of the closed circuit as will a removal of the tag 222 or 222′ therefrom. The tampering alarm will thereby be activated and appropriate action can be taken.

Similarly with regard to FIGS. 13 and 14, an attachment assembly 240′ may be fixedly secured to the object being monitored such as when the object is a storage container 270 for temperature-sensitive fluid, such as blood. The tag 222, 222′ would be added to the circuitry of the attachment assembly 240′ as represented in detail in FIG. 14. More specifically, the tag 222, 222′ would be connected such as by terminals 272 so as to complete the circuit defined, at least in part by conductive segments 274. Similar to the embodiment of FIG. 12, the attachment assembly 240′ has the conductive segments 274 preferably formed from an electro-conductive coating and/or electro-conductive paint. It should be obvious that the precise configuration of the formed circuitry defined by the conductive segments 274 and the terminals 272 may assume a variety of different configurations other than that demonstrated in FIG. 14. Also the circuitry of the attachment assembly 240′ may include similarly structured and operative antenna array including a transmitting antenna 253′ and a receiving antenna 255′.

The tampering facility and capabilities of the attachment assembly 240′ are also demonstrated either by a removal of the tag 222, 222′ from the terminals 272 causing a breaking or failure of the circuit. A failure of the circuit can also occur by an attempted removal of the attachment assembly 240′ from the animate object or container 270 being monitored or by a break in any one of the conductive segments 274.

Communication from the tag 222, 222′ can occur by an RF frequency link with the reader 218 and eventually to the host controller 214. Alternatively, the tag 222, 222′, being active (containing its own power source) can facilitate communication by means of the antenna array 253′, 255′. Moreover, the tag 222, 222′ can communicate with the host controller 214 in the event of a non-compliant status of the characteristic being monitored or in the event of attempted tampering as set forth above.

With regard to the disclosed embodiments contained herein, it is also recognized that if desired the tag can be effectively positioned at or near an object being monitored, with the reader only coming into communicative proximity with the tag at certain times. In such an embodiment, such as for monitoring conditions at a specific location, such as in a tunnel or other facility, periodic checks can be established merely by passing the reader into or through that communicative proximity or turning on or activating the reader at certain times so as to identify a compliant or non-compliant state(s) being monitored at the tag, detect specific details regarding the current state(s) being monitored at the tag, and/or collect stored data maintained at the tag regarding the state(s) over a period of time.

Since many modifications, variations and changes in detail can be made to the described preferred embodiment of the invention, it is intended that all matters in the foregoing description and shown in the accompanying drawings be interpreted as illustrative and not in a limiting sense. Thus, the scope of the invention should be determined by the appended claims and their legal equivalents.

Now that the invention has been described, 

1. A system for monitoring an object on a real time basis, said system comprising: at least one host controller, at least one tag associated with the object being monitored and secured thereto, a reader, said reader and said tag cooperatively structured to establish communication there between when within a communicative proximity range from one another, said tag comprising a probe structured and disposed relative to the object to monitor at least one predetermined characteristic associated with the object, said reader structured to identify at least a status of said predetermined characteristic being monitored to said host controller, said predetermined characteristic comprising temperature, and said probe structured to monitor the temperature associated with the object.
 2. A system as recited in claim 1 wherein said probe is structured to monitor the temperature associated with the object within a predetermined range, said predetermined range of temperature being variably programmed by wireless communication with a program application.
 3. A system as recited in claim 1 wherein said tag comprises memory facilities structured to store object data.
 4. A system as recited in claim 1 wherein said tag further comprises a tracking facility structured to provide location data of the object being monitored.
 5. A system as recited in claim 4 wherein said tracking facility is structured for activation by radio frequency communication at least between said tag and said reader.
 6. A system as recited in claim 4 wherein said tracking facility comprises an active mode regulated by said reader, said active mode defined by a predetermined communication link between said tag and said host controller.
 7. A system as recited in claim 6 wherein said tracking facility includes a GPS capabilities.
 8. A system as recited in claim 7 wherein said communication link comprises an activating link from said host controller to said reader and from said reader to said tag.
 9. A system as recited in claim 8 wherein said communication link further comprises a locating link from said tag to a satellite and from said satellite to said host controller or to said reader.
 10. A system for monitoring an object on a real time basis, said system comprising: at least one host controller, at least one tag associated with the object being monitored and secured thereto, a reader, said reader and said tag cooperatively structured to establish communication there between when within a communicative proximity range from one another, said tag comprising a probe structured and disposed relative to the object to monitor at least one predetermined characteristic associated with the object, said reader structured to identify at least a status of said predetermined characteristic being monitored to said host controller, said predetermined characteristic comprising pressure, and said probe structured to monitor the pressure associated with the object.
 11. A system as recited in claim 10 wherein said probe is structured to monitor the pressure associated with the object within a predetermined range, said predetermined range of pressure being variably programmed by wireless communication with a program application.
 12. A system for monitoring an object on a real time basis, said system comprising: at least one host controller, at least one tag associated with the object being monitored and secured thereto, a reader, said reader and said tag cooperatively structured to establish communication there between when within a communicative proximity range from one another, said tag comprising a probe structured and disposed relative to the object to monitor at least one predetermined characteristic associated with the object, said reader structured to identify at least a status of said predetermined characteristic being monitored to said host controller, said predetermined characteristic comprising vibration, and said probe structured to monitor the vibration associated with the object.
 13. A system as recited in claim 12 wherein said probe is structured to monitor the vibration associated with the object within a predetermined range, said predetermined range of pressure being variably programmed by wireless communication with said program application.
 14. A system for monitoring an object on a real time basis, said system comprising: at least one host controller, at least one tag associated with the object being monitored and secured thereto, a reader, said reader and said tag cooperatively structured to establish communication there between when within a communicative proximity range from one another, said tag comprising a probe structured and disposed relative to the object to monitor at least one predetermined characteristic associated with the object, said reader structured to identify at least a status of said predetermined characteristic being monitored to said host controller, said predetermined characteristic comprising motion, and said probe structured to monitor the motion associated with the object.
 15. A system as recited in claim 14 wherein said probe is structured to monitor the motion associated with the object within a predetermined range, said predetermined range of motion being variably programmed by wireless communication with a program application.
 16. A system for monitoring an object on a real time basis, said system comprising: at least one host controller, at least one tag associated with the object being monitored, a reader, said reader and said tag cooperatively structured to establish communication there between when within a communicative proximity range from one another, said tag comprising a probe structured and disposed relative to the object to monitor at least one predetermined characteristic associated with the object, said reader structured to communicate at least a status of said predetermined characteristic being monitored to said host controller, an attachment assembly structured to dispose said tag in monitoring proximity to the object being monitored, and said attachment assembly comprising a circuit electrically connected to said tag and securable to a location at which said tag is disposed.
 17. A system as recited in claim 16 wherein said attachment assembly is fixedly secured in monitoring proximity to the object being monitored.
 18. A system as recited in claim 16 wherein said attachment assembly is removably attached in monitoring proximity to the object.
 19. A system as recited in claim 16 wherein said reader is structured to transmit data received from said tag to said host controller, said host controller responsive to the tag transmitted data and structured to be determinative of location parameters of said tag. 